Doc.: IEEE 802.11-11/0081r0 Submission Title –Author List Date: 2013-01-10 Authors: January 2013...
-
Upload
marcia-bailey -
Category
Documents
-
view
214 -
download
2
Transcript of Doc.: IEEE 802.11-11/0081r0 Submission Title –Author List Date: 2013-01-10 Authors: January 2013...
doc.: IEEE 802.11-11/0081r0
Submission
Title –Author ListDate: 2013-01-10
Name Affiliations Address Phone email James Wang MediaTek. 2860 Junction Ave, San Jose,
CA 95134 +1 408 526 1899-88109
Sayantan Choudhury Nokia 2075 Allston Way, Suite 200, Berkeley, CA 94704
+1 510 599 9268
George Calcev Huawei Rolling Meadows, IL USA [email protected]
Eldad Perahia Intel Corp. [email protected]
Shahrnaz Azizi Intel Corp. [email protected]
Tom Tetzlaff Intel Corp. [email protected]
Thomas Kenney Intel Corp. [email protected]
Hongyuan Zhang Marvell [email protected]
Sudhir Srinivasa Marvell [email protected]
Su Khiong Yong Marvell [email protected]
Yongho Seok LG Electronics LG R&D Complex Anyang-Shi, Kyungki-Do, Korea
+82-31-450-1947 [email protected]
Jinsoo Choi LG Electronics
Jeongki Kim LG Electronics
Jin Sam Kwak LG Electronics
Vinko Erceg Broadcom [email protected]
Ron Porat Broadcom [email protected]
Rojan Chitrakar Panasonic [email protected]
Ken Mori Panasonic [email protected]
Harya Wicaksana Panasonic [email protected]
Authors:
January 2013
Name , Company.Slide 1
doc.: IEEE 802.11-11/0081r0
Submission
Name Affiliations Address Phone email Sameer Vermani Qualcomm
Eugene Baik Qualcomm
Lin Yang Qualcomm
Hemanth Sampath Qualcomm
Richard Van Nee Qualcomm
Allert Van Zelst Qualcomm
VK Jones Qualcomm
Sun, Bo ZTE [email protected]
Lv, Kaiying ZTE [email protected]
Huai-Rong Shao Samsung [email protected]
Chiu Ngo Samsung [email protected]
Minho Cheong ETRI 138 Gajeongno, Yuseong-gu, Dajeon, Korea
+82 42 860 5635 [email protected]
Jae Seung Lee ETRI [email protected]
Hyoungjin Kwon ETRI [email protected]
Jaewoo Park ETRI [email protected]
Sok-kyu Lee ETRI [email protected]
Klaus Doppler Nokia
January 2013
Slide 2 Name , Company.
doc.: IEEE 802.11-11/0081r0
Submission Name, Affiliation
January 2013
Slide 3
Name Affiliations Address Phone email Zander Lei I2R 1 Fusionopolis Way, #21-01
Connexis Tower, Singapore 138632
+65-6408 2000 [email protected]
Li Chia Choo I2R [email protected]
Zhou Yuan I2R [email protected]
Sumei Sun I2R [email protected]
Chin Keong Ho I2R [email protected]
Osama Aboul Magd Huawei [email protected]
Young Hoon Kwon Huawei [email protected]
Betty Zhao Huawei [email protected]
David Yangxun Huawei [email protected]
Bin Zhen Huawei [email protected]
ChaoChun Wang MediaTek [email protected]
James Wang MediaTek [email protected]
Jianhan Liu MediaTek [email protected]
Vish Ponnampalam MediaTek [email protected]
James Yee MediaTek [email protected]
Thomas Pare MediaTek [email protected]
Kiran Uln MediaTek [email protected]
Anna Pantelidou Renesas Mobile
Juho Pirskanen Renesas Mobile
Timo Koskela Renesas Mobile
Liwen Chu STMicroelectronics
George Vlantis STMicroelectronics
doc.: IEEE 802.11-11/0081r0
Submission
Name Affiliations Address Phone email Minyoung Park Intel Corp. [email protected]
Tom Tetzlaff Intel Corp. [email protected]
Emily Qi Intel Corp. [email protected]
Su Khiong Yong Marvell [email protected]
Hongyuan Zhang Marvell [email protected]
Sudhir Srinivasa Marvell [email protected]
Yongho Seok LG Electronics LG R&D Complex Anyang-Shi, Kyungki-Do, Korea
+82-31-450-1947 [email protected]
Jinsoo Choi LG Electronics
Jeongki Kim LG Electronics
Jin Sam Kwak LG Electronics
Matthew Fischer Broadcom 190 Mathilda Place, Sunnyvale, CA
+1 408 543 3370 [email protected]
Eric Wong Broadcom [email protected]
Yong Liu Broadcom [email protected]
Rojan Chitrakar Panasonic [email protected]
Ken Mori Panasonic [email protected]
January 2013
Name , Company.Slide 4
doc.: IEEE 802.11-11/0081r0
Submission
Name Affiliations Address Phone email Simone Merlin Qualcomm 5775 Morehouse Dr,
San Diego, CA 8588451243 [email protected]
Alfred Asterjadhi Qualcomm
Amin Jafarian Qualcomm
Santosh Abraham Qualcomm
Menzo Wentink Qualcomm
Hemanth Sampath Qualcomm
VK Jones Qualcomm
Sun, Bo ZTE [email protected]
Lv, Kaiying ZTE [email protected]
Huai-Rong Shao Samsung [email protected]
Chiu Ngo Samsung [email protected]
Minho Cheong ETRI 138 Gajeongno, Yuseong-gu, Dajeon, Korea
+82 42 860 5635
Jae Seung Lee ETRI [email protected]
Hyoungjin Kwon ETRI [email protected]
Jaewoo Park ETRI [email protected]
Sok-kyu Lee ETRI [email protected]
Klaus Doppler Nokia
Chittabrata Ghosh Nokia
Esa Tuomaala Nokia
January 2013
Name , Company.Slide 5
doc.: IEEE 802.11-11/0081r0
Submission Name, Affiliation
January 2013
Slide 6
Name Affiliations Address Phone email Shoukang Zheng I2R 1 Fusionopolis Way, #21-01
Connexis Tower, Singapore 138632
+65-6408 2000 [email protected]
Haiguang Wang I2R [email protected] Wai Leong Yeow I2R [email protected] Zander Lei I2R [email protected] Yuan Zhou I2R [email protected] Osama Aboul Magd Huawei Osama.AboulMagd@huawe
i.com
Young Hoon Kwon Huawei [email protected]
Betty Zhao Huawei [email protected]
David Yangxun Huawei [email protected]
Bin Zhen Huawei [email protected]
ChaoChun Wang MediaTek [email protected]
Jianhan Liu MediaTek [email protected]
Vish Ponnampalam MediaTek [email protected]
James Yee MediaTek [email protected]
Thomas Pare MediaTek [email protected]
Kiran Uln MediaTek [email protected]
Anna Pantelidou Renesas Mobile
Juho Pirskanen Renesas Mobile
Timo Koskela Renesas Mobile
Liwen Chu STMicroelectronics
George Vlantis STMicroelectronics
doc.: IEEE 802.11-11/0081r0
Submission
Type 0 Sectorization Scheme(IEEE11-12-0852-00-00ah Sectorization for Hidden Node Mitigation by Huawei )
• Sectorization was proposed by Huawei to mitigate hidden node (because the number of active nodes is reduced in a specific sector) – AP divides the space in multiple sectors and use a TDM approach to allow STA transmissions
in one sector at the time– Stations are allowed to transmit and receive data only in the time interval corresponding with
their sector (called as Sector Interval in the drawing)– Some time interval can be left for channel access of all sectors at the same time
• Note 1: SFD 4.2.I provides the basis for this sectorization scheme• Note 2: This approach applies to either BSS with only sectorized (no omni)
beam or BSS with both sectorized beam and omni beam
Slide 7
BeaconSector
1Access STAs in
Sector 1
BeaconSector
2Access STAs in
sector 2
BeaconSector
3Access STAs in
sector 3
OmniBeacon
Access all STAs in
the BSS
Sector Interval 1 Sector Interval 2 Sector Interval 3 Omni Interval
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
Type 1 Sectorization Scheme(IEEE11-12-1355-02-00ah Sectorized Beam Operation – Follow Up by January 2013 et
al, SDF:4.6)
• A proposal introducing a more flexible sectorized beam operation was presented in the IEEE f-to-f September, 2011– AP can switch back and forth between sectorized beam(s) and omni beam – Sectorized beam is used only when AP is aware of the STA’s sector either in scheduled
transmission such as RAW or during a TXOP of a STA. AP switches back to omni otherwise. – The sectorized receive beam is used in conjunction with the sectorized transmit beam within an
TXOP– AP indicates the sectorized beam operation in Beacons, Probe Response, or Association
Response.• Note 1: SDF 4.6 provides the basis for this sectorization operation• Note 2: This proposal requires an AP to be able to transmit/receive both omni and
sectorized beam (We assumes that only AP (not STA) uses the sectorized beam)• Note 3: The forming of the sector beam is implementation specific
Slide 8
Beacon Beacon
Sector 2
BeaconAP
STA
RAW1 RAW1 RAW2 RAW2 RAW3TXOP
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
Type 1 Sectorization Scheme
• A simple solution to the issues described in the preceding chart is to employ the omni-beam transmission to set up proper protection duration (for both AP and STAs) at the beginning of a TXOP and then use the sectorized beam for the remainder of the duration
• This allows STAs to set their NAVs properly and prevents STAs in same BSS and OBSS AP/STA from accessing the channel at the same time
Slide 9
AP
STA
Omni-Beam Duration
NAV
NAV
TXOP
Sectorized-Beam Transmission and Reception Duration
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
Type 1 Sectorization Scheme
• During the sectorized beam transmission, some SO (spatially-orthogonal) OBSS STAs and APs will not receive the AP1 and STA1 signals.
• To enhance the spatial re-use of the medium, the SO OBSS STA or AP is allowed to access the channel during the sectorized beam transmission protected duration
Slide 10
AP1
STA1
Omni-Beam Duration
NAV
NAV
TXOPSectorized-Beam Transmit and Receiver Duration
AP1
STA1
SO OBSS STA2
SO OBSS AP2
OBSS STA3
Spatial Re-use by out-of-range OBSS STAs and APs
Note: SO (Spatially Orthogonal) OBSS STA/AP is defined as the OBSS STA/AP which can receive the omni transmission but not the sectorized transmission from AP1 and not the transmission from STA1
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
Spatial Re-use Channel Access Rules (SFD 4.6)
• When the protection is set up by omni transmission for a duration within a TXOP and if the SO condition is confirmed by an OBSS STA/AP, the OBSS STA/AP can cancel its NAV to initiate a new SO exchange starting with a non-BF RTS/CTS.
• Once an AP switches to the sectorized beam transmission during an exchange, it shall continue with greenfield sectorized beam transmission for the remainder of the protected duration
• Note: SO (Spatially Orthogonal) condition is defined as a OBSS STA/AP which receives the omni transmission but not the sectorized transmission from the AP (which is either the TXOP holder or responder) and not the transmission from the STA (which is either the TXOP responder or holder).
Slide 11
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
Part 1: Type 1 Sectorization SchemeOBSS Simulation
Omni vs. Sectorization
January 2013
Slide 12
doc.: IEEE 802.11-11/0081r0
Submission
-2000 -1500 -1000 -500 0 500 1000 1500 2000-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e i
n m
ete
rs
OBSS 3 Cells, Omni Antenna, AP-AP Separation=1.5 km-2000 -1500 -1000 -500 0 500 1000 1500 2000
-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e in
met
ers
OBSS 3 Cells, Omni Antenna, AP-AP Separation=1.5 km
OBSS Scenario using Omni AntennasAP-STA Intereference
• # STAs/BSS: 1000 (uniform distribution)
• BSS radius:1.13 km• AP-AP separation: 1.5km• Link Budget per IEEE 11-11-0053
– RX Ant gain = 0
• Receive Sensitivity = -98 dBm• CCA = -88 dBm• # OBSS STAs to BSS A
– 450 (out of 2000)• # OBSS STAs, potentially interfering
with AP_A (due to CCA 10dB higher than Sensitivity) – 378 (out of 2000)
• Most of OBSS STAs (378 out of 450) is below CCA level (interfering with AP_A)
January 2013
Slide 13
AP_A
AP_B
AP_C
# OBSS STAs (interference to AP_A)
# OBSS STAs to BSS A
BSS_A
BSS B
BSS C
AP_A
Circle=1km radius
doc.: IEEE 802.11-11/0081r0
Submission
An Example of a Sectorized Beam Implementation
January 2013
Slide 14
• Use 6 panel antennas (60 degree each) to create 6 sectors
• When TX power is equally split into 6 antennas, an omni beam is formed
• AP switch between omni and directional beams
• Peak EIRP for the sectorized beam the same as that for the omni beam (FCC rules)
doc.: IEEE 802.11-11/0081r0
Submission
OBSS Scenarios with Sectorized BeamsAP-STA Interference
January 2013
Slide 15
• # STAs/BSS: 1000• BSS radius:1km• # OBSS STAs to BSS A
– 450 (out of 2000)• Avg. # OBSS STAs, potentially
interfering with AP_A (due to CCA <0) – 89
• Reduction in Interfering OBSS STAs – 1 - 89/378 = 76%
• Avg. # Spatially Orthogonal STAs (Increase in spatial re-use)– 440 (out of 450) = 98%
– Number of BSS_A STAs in Sectorized Beam = 272 (reduced from 1000)
-2000 -1500 -1000 -500 0 500 1000 1500 2000-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e i
n m
ete
rs
OBSS 3 Cells, Sectorized Beam Antenna, AP-AP Separation=1.5 km
-2000 -1500 -1000 -500 0 500 1000 1500 2000-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e i
n m
ete
rs
OBSS 3 Cells, Sectorized Beam Antenna, AP-AP Separation=1.5 km
AP_A
AP_B
AP_C
BSS_A
BSS B
BSS C
# OBSS STAs (interference to AP_A)
Spatially Orthogonal STAs
doc.: IEEE 802.11-11/0081r0
Submission
-2000 -1500 -1000 -500 0 500 1000 1500 2000-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e i
n m
ete
rs
OBSS 3 Cells, Sectorized Beam Antenna, AP-AP Separation=1.5 km
OBSS Scenarios: AP-AP interference
January 2013
Slide 16
• AP-to-AP path loss model currently not defined.
• Estimating range using LTE Base Station to Relay, NLOS model (at the Rooftop level):
• 1.6km• If AP antenna is above rooftop, AP should
see other APs 1.5km away• Note that if all AP using omni antenna, then
all 3 APs compete for medium all the time• Note that if AP_A using sectorized beam
antenna, then spatial re-use AP_B (and AP_C) is
• 5/6 = 83% (5 out of 6 sectors)
-2000 -1500 -1000 -500 0 500 1000 1500 2000-2000
-1500
-1000
-500
0
500
1000
1500
2000
Distance in meters
Dis
tanc
e in
met
ers
OBSS 3 Cells, Omni Antenna, AP-AP Separation=1.5 km
AP_A
AP_B
AP_C
1.5km
AP_B
AP_C
doc.: IEEE 802.11-11/0081r0
Submission
Simulation Results -1
• Simulation shows that – Sectorized beam operation reduces the number of interferring
OBSS STAs by 76% – Sectorized beam reduces the STAs in BSS_A from 1000 (Omni) to
272 (Sectorized beam)– Sectorized beam operation allows 98% of OBSS STAs to spatial
re-use without causing interference– Outdoor APs can hear each other from long distance since AP-AP
path loss is significantly lower than AP-STA. – Sectorized beam operation allows AP_B and AP_C to spatial re-
use 83% of time– If CCA is 10dB higher than receiver sensitivity, 84% of OBSS
STAs (in BSS B and BSS C) interferes with AP_A
January 2013
Slide 17
doc.: IEEE 802.11-11/0081r0
Submission
Simulation Results - 2
• Most of OBSS STA is SO regardless the separation of Aps
• # Interfering OBSS STAs reduces significantly when the difference in CCA and Rcvr. Sensitivity levels is reduced (from 10 dB to 3 dB)
• Ratio of # SO OBSS STAs to # OBSS STAs reduces slightly when the difference in CCA and Rcvr. Sensitivity levels is reduced (from 10 dB to 3 dB)
January 2013
Slide 18
500 1000 15000
500
1000
1500
AP-AP Separation in Meters
Per
cent
ag
e
Omni vs Sectorized Beam, # STAs in BSS B+ BSS C = 2000
# OBSS STA in BSS B+BSS C
# Interferring OBSS STA (AP_A w. Omni Ant)
# SO OBSS STA (AP_A w. Sector Ant)
# interferring OBSS STA (AP_A w. Sector Ant)
500 1000 15000
500
1000
1500
AP-AP Separation in Meters
Per
cent
ag
e
Omni vs Sectorized Beam, # STAs in BSS B+ BSS C = 2000
# OBSS STA in BSS B+BSS C
# Interferring OBSS STA (AP_A w. Omni Ant)
# SO OBSS STA (AP_A w. Sector Ant)
# interferring OBSS STA (AP_A w. Sector Ant)
CCA-Rcvr Sensivity=10 dB
CCA-Rcvr Sensivity=3 dB
doc.: IEEE 802.11-11/0081r0
Submission
Part 1: More Details on Type 1 Sectorization Operation
January 2013
Slide 19
doc.: IEEE 802.11-11/0081r0
Submission
IE for Type 1 Sectorization Scheme
• I.E. for Type 1 Sectorization Scheme – S. Scheme: 1 (Type 1 Sectorization scheme)– P. Training ON/OFF Indicator: 0 - Periodic Training not Present, 1
– Present– Training Period (# of Beacon Intervals for the periodic training)– Remaining BI: remaining beacon intervals to the periodic training
(including the current beacon interval)
January 2013
Slide 20
IE # # Bytes
8 bits
S. Scheme
1 bit
P. Training Ind.
1 bit
Rvd
TBD bits
Training Period
6 bits
Remaining BI
6 bits
doc.: IEEE 802.11-11/0081r0
Submission
Spatially-Orthogonal Conditions Detection
• Previously, 4 spatially orthogonal condition detection schemes were proposed (11-12-1355-02-00ah).
• AP follows one the 4 transmission sequences to allow STAs to set up NAV during omni transmission and switch to sectorized beam transmission
• Propose to include a 1-bit sector ID indicator (from reserved bits) in CTS-to-self (which precedes SO conditions 1 or 2) to facilitate the detection of the SO conditions
January 2013
Slide 21
CTS-to-SelfAP1
STA1
TXOP Protection
Sectorized Beam
NAV
Omni
Omni w. SO Indicator SO Condition 1 or Condition 2
doc.: IEEE 802.11-11/0081r0
Submission
Sectorized Beam Training Request/Feedback -1
• SDF R.4.2.I 3: STA can optionally feedback sector/group ID• AP indicates the sectorized beam operation• STA joining a sectorized beam operation BSS shall indicate
whether it supports sectorized beam feedback in the sectorized beam feedback capability field (1=support)
• STA indicates through capability exchange that it support request/feedback
• Propose to re-use the HT Variant Control Link Adaptation Field (setting MAI=14, or MRQ=0, MSI=7) for requesting or indicating “Sector Training”– TXASSR (transmit antenna selection request) Sector training request– HT NDP Announcement field =1 Indicate NDP sounding (preceding training
packets)
• Use VHT Sounding NDP with Nsts=1 for sector beam training
January 2013
Slide 22
doc.: IEEE 802.11-11/0081r0
Submission
Sectorized Beam Training Request/Feedback -2
• Propose to use a VHT Action frame (8.5.23.1 in 11ac) for (solicited and unsolicited) Sector ID feedback.– VHT action = 3 (or higher)– Sector ID index (format TBD)
January 2013
Slide 23
Order Information
1 Category
2 VHT Action
3 Sector ID Index
(Sector Training Req)
(Sector Training Announcement) HT NDP Announcement=1 VHT Sounding
NDP with Nsts=1
Sector ID FB
AP
STA
doc.: IEEE 802.11-11/0081r0
Submission
Part 2: Type 0 Sectorization Scheme: More Details
January 2013
Slide 24
doc.: IEEE 802.11-11/0081r0
Submission
Type 0 Sectorization Mode• In this mode the AP broadcast some of the beacons sector beamformed in regular schedule• There are two categories of station operation modes:
• Sectorized STA• Non sectorized STA
• Those sectorized STAs that received the beamformed beacon are allowed to transmit data during the sector interval.
• All the stations (sectorized STAs and non-sectorized) are allowed to transmit during omni interval
• The non-sectorized STAs are allowed to transmit during the sector interval even if they don’t hear the sector beamformed beacon but they can transmit in omni interval.
• The mode of operation (sectorized or non-sectorized) for STA (or traffic) is established at association ( by the type of station or just by the type of traffic if a STA carries multiple types of traffic)
• After association a STA could change its mode of operation – for instance via a management frame from AP or via indications in beacons
• Example of operation: offloading stations/traffic could transmit with no restrictions, the sensor traffic transmit only during their sector time interval
• Besides the beamformed beacon broadcast, the AP operates without spatial restrictions, being able to receive from and transmit to all directions
• Stations that are allowed to transmit have no restrictions in transmit direction• Note: The sector only BSS would be realized if all STAs are sectorized STA. This would
eliminate the needs for omni reception by AP.
January 2013
Slide 25
doc.: IEEE 802.11-11/0081r0
Submission
Type 0 sectorization
January 2013
Slide 26
BeaconSector
1Access STAs in
Sector 1
BeaconSector
2Access STAs in
sector 2
BeaconSector
3Access STAs in
sector 3
OmniBeacon
Access all STAs in
the BSS
Sector Interval 1 Sector Interval 2 Sector Interval 3 Omni Interval
Beamformed Beacon CoverageAP coverage Sectorized STA
Non-sectorized STA
doc.: IEEE 802.11-11/0081r0
Submission
IE for Type 0 Sectorization Scheme
• Type 0 sectorization schemes should be indicated in beacon, probe response, association confirmation to inform STAs.
• At each beacon interval, a different sector is used
• Proposed IE for Type 0 Scheme– S Scheme: 0 - Type 0 sectorization scheme– the complete rotation period (# of beacon intervals) for all sectors– omni-directional sector indicator: 1 = omni, 0 = non-omni (In omni, all STAs can access the medium) – the current sector ID – Group ID 1, …, Group ID k corresponding to the current sector ID– the sub-period for current sector ID (sub-period* integer = complete period)
January 2013
Slide 27
Sector 0 Sector 0Sector 1 Sector 2 Sector 1
Complete rotation period for all sectorsSub-period for Sector 1
IE # # Bytes C.R. Period Sector ID Sub-period
8 bits 6 bits 3 bits 5 bits
S. Scheme
1 bit
Rvd
7 bits
O. Ind
1 bit
Group ID1 Group ID k
? bits ? bits
doc.: IEEE 802.11-11/0081r0
Submission
Straw Poll 1
• Do you support the proposed IE for indicating Type 1 Sectorization as described in Slide 16
January 2013
Slide 28
doc.: IEEE 802.11-11/0081r0
Submission
Straw Poll 2
• Do you support to include an 1 bit early sector indicator from reserved bits for the sectorized transmission in NDP CTS-to-self (which precedes SO condition 1 or SO Condition 2) to facilitate the detection of SO conditions
January 2013
Slide 29
doc.: IEEE 802.11-11/0081r0
Submission
Straw Poll 3
• Do you support to use the – HT Variant HT Control Link Adaptation Field for
• Requesting sector training, • NDP announcement,
– Sector ID feedback frame
as described in Slides 18 and 19
January 2013
Slide 30
doc.: IEEE 802.11-11/0081r0
Submission
Straw Poll 4
• Do you support the proposed IE for indicating Type 0 Sectorization as described in Slide 23
January 2013
Slide 31
doc.: IEEE 802.11-11/0081r0
Submission
Motion 1
• Move to include the IE for indicating Type 1 Sectorization as described in Slide 16
January 2013
Slide 32
doc.: IEEE 802.11-11/0081r0
Submission
Motion 2
• Move to include an 1 bit early sector indicator from reserved bits for the sectorized transmission in NDP CTS-to-self (which precedes SO condition 1 or SO Condition 2) to facilitate the detection of SO conditions
January 2013
Slide 33
doc.: IEEE 802.11-11/0081r0
Submission
Motion 3
• Move to use the – HT Variant HT Control Link Adaptation Field for
• Requesting sector training, • NDP announcement,
– Sector ID feedback frame
as described in Slides 18 and 19
January 2013
Slide 34
doc.: IEEE 802.11-11/0081r0
Submission
Motion 4
• Move to include the IE for indicating Type 0 Sectorization as described in Slide 23
January 2013
Slide 35
doc.: IEEE 802.11-11/0081r0
Submission
BACKUP CHARTS
January 2013
Slide 36
doc.: IEEE 802.11-11/0081r0
Submission
SO (Spatially Orthogonal) Condition - 1
• AP can use omni-preamble to set up TXOP protection for the sectorized beam transmission.
• Once the proper TXOP protection is set up with a long preamble, the sectorized transmission (with greenfield BF) shall be used for the remainder of the TXOP.
• SO condition is confirmed by an OBSS STA/AP not receiving – STA1’s transmission (OBSS STA expects a following STA1 transmission when it sees Ack Ind= 00, 10, Ack Ind=11/Ack
Policy=00 in the AP1 Omni packet packet), – and the AP1’s sectorized transmission portion within the long packet
Slide 37
Omni Packet Long Packet
ACK
AP1
STA1
Example TXOP ProtectionOmni-
PreambleSectorized Beam
NAV
NAV
Can be spatially re-used by SO OBSS STA and AP
ACK or RSP
NAV protected BF duration
January 2013
doc.: IEEE 802.11-11/0081r0
Submission
SO (Spatially Orthogonal) Condition - 2
• AP can also use the short-preamble with omni-transmission to set up TXOP protection for the sectorized beam transmission.
• As shown in the examples, the TXOP protection is set up at the second transmission by AP
• Once the proper TXOP protection is set up, the sectorized transmission (with greenfield BF) shall be used for the remainder of the TXOP.
• SO condition is confirmed by an OBSS STA/AP not receiving – STA1’s transmission (OBSS STA expects a following STA1 transmission when it sees Ack Ind= 00, 10, or Ack
Ind=11/Ack Policy=00 in the AP1 Omni packet packet)), – and the AP1’s sectorized transmission (following the omni packet with ACK Policy=Block Ack*).
Slide 38
Omni packet
ACK or RSP
short packetAP1
STA1
Example TXOP Protection
Omni-Beam Sectorized Beam
NAV
NAVCan be spatially re-used by SO OBSS STA and AP
NAVACK or RSP
ACK Policy=BACK or NO ACK*
short packet
*Note: maybe easier to have a new indicator in SIG for a following sectorized beam packetJanuary 2013
doc.: IEEE 802.11-11/0081r0
Submission
SO (Spatially Orthogonal) Condition 3 - RTS/CTS
January 2013
Slide 39
RTS Long Preamble
ACK
AP1
STA1
Example TXOP ProtectionOmni-
PreambleSectorized Beam
NAV
NAV
Can be spatially re-used by SO OBSS STA and AP
CTS
NAV protected BF duration
RTS Short Preamble
ACK
AP1
STA1
NAV
NAV
Can be spatially re-used by SO OBSS STA and AP
CTS
NAV protected BF duration
Ack Policy=BACK or No ACK*
Short Preamble
Short Preamble
*Note: maybe easier to have a new indicator in SIG for a following sectorized beam packet
doc.: IEEE 802.11-11/0081r0
Submission
SO (Spatially Orthogonal) Condition - 4
• The followings illustrate an exchange initiated by STA
Slide 40
long packetAP
STA
TXOPOmni-Preamble Sectorized Beam
NAV
NAV
Can be spatially re-used by out-of-rang OBSS STA and AP, if the AP transmission can be identified as the response frame to PS-Poll/Trigger from STA
PS-Poll/Trigger/ Other Frame
ACK or RSP
short packetAP
STA
TXOPOmni-Preamble Sectorized Beam
NAV
NAV
PS-Poll/Trigger/ Other Frame
ACK or RSP
short packet
Can be spatially re-used by out-of-rang OBSS STA and AP (if the AP transmission can be identified as the response frame to PS-Poll/Trigger)
Ack Policy=BACK or No ACK*
Note: If the AP transmission cannot be identified as a response to STA’s frame, the SO OBSS condition to be confirmed by slide 14 or 15 *Note: maybe easier to have a new indicator in SIG for a following sectorized beam packet
January 2013